DE1161311B - Transmission circuit for forwarding information stored in a magnetic core that can be connected - Google Patents

Description

Transmission circuit for passing on information stored in a saturable magnetic core Addendum to patent: 1 142 452 The main patent relates to a transmission circuit for passing on information stored in a saturable magnetic core, the remanent flux of which is almost equal to its saturation flux, in the form of information that occurs when the magnetic core is reversed Current pulse to another magnetic core or another load, in which the transfer element between the magnetic core used for storage and the load, which prevents undesired impulses from taking effect when the information is passed on, is a magnetic core with two stable remanence states of opposite polarity and the one used for storage Magnetic core has a pronounced threshold value flooding.

The subject of the invention is an advantageous further development of the arrangement according to the main patent, which makes it possible to make such arrangements in a simple manner Way to build basic logic circuits with which all statements connections can be realized. This is according to the invention in an arrangement according to the main patent achieved in that when the information is entered into the first magnetic core The magnetization of this magnetic core changes into the opposite remanence state The magnetization of the second magnetic core is also reversed and only when the magnetization is reversed of the second magnetic core sends the information to a third magnetic core serving as a load is delivered.

The invention is illustrated with reference to some in the drawings Embodiments described in more detail. It shows F i g. 1 the hysteresis loop a magnetic material which is necessary for the memory cores of the invention Has threshold value, F i g. 2 shows the circuit diagram of a logical AND circuit with three Inputs, F i g. 3 shows the circuit diagram of a logical OR-BUT circuit, FIG. 4th the circuit diagram of an adder for two binary digits, F i g. 5 the circuit diagram an INVERTER logic circuit and F i g. 6 the relative timing of the current pulses required to operate the circuits described.

In Fig. 1 is the hysteresis curve of a ferrite material with rectangular behavior shown. The magnetic field strength H is plotted on the horizontal axis. The remanent induction B, almost reaches the saturation induction, and the coercive force Ho represents a pronounced threshold value, which is expressed in the drawing comes that the curve near Ho is practically right-angled Has kink. The storage cores should consist of such a material, however the only requirement made on the coupling cores is that their material should have a hysteresis loop with two stable remanence points.

In the drawings, the windings on the magnetic cores are for illustration of the winding direction with a point at one end. In the following the remanence state, which a nucleus seeks to occupy when it flows from a current into the marked one The end of its winding has been magnetized, the binary zero and the opposite Remanence state assigned the binary one and from a state zero and one State one spoken.

F i g. 2 shows the circuit diagram of a logical AND circuit with three Inputs x, y and z. A signal is only produced at its output if everyone of their inputs is excited. The input signals are provided by three pulse generators IxB, IyB and 1z $, which are also the outputs of logic circuits can, to the input windings 10 x, 10y and 10z on three similarly labeled Memory cores 12. Each of the memory cores 12 carries two more Windings, a sliding winding 14 and an output winding 16. The sliding windings 14, connected in series, are fed with clock pulses from the pulse generator 1, 4. Each storage core 12 has a coupling core 28, over its winding 26 and a Resistor 24 the output winding 16 of this memory core together with the output windings of the remaining storage cores are connected to the winding 20 of an output core 22 is. The coupling cores 28 also carry windings 30, which are connected in series to the power source Ix are laid. This power source can either be a direct current or a clock pulse deliver. The output core 22 carries the output winding 32, which: the output of the AND circuit represents.

The pulse generators I, 3 at the input of the circuit can become one Time B can be actuated. All three deliver an impulse to the at the same time Input windings 10, the cores 12, which were initially in the zero state, brought to the state one, since the pulses at the unmarked ends of the windings occur. The resulting flow changes cause everyone the output windings 16 of the memory cores 12 have a voltage and a current flows into the unmarked end of the windings 26 of the associated coupling cores 28, which now also move from state zero to state one. While the coupling cores 28 change their state, each of the windings 26 is the flowing Current has a high resistance, and that at the winding 20 of the output core The resulting tension is only slight. Will deliver at a later date the power source in a clock pulse and sets the coupling cores. 28 back to zero. At the marked end of the windings 26, a voltage arises that drives a current through windings 16 which resets memory cores 12 want. However, through a suitable choice of the winding ratio, it can be achieved that the applied field strength is below the threshold value of the storage cores, the coercive force, remain. However, these currents add up at the winding 20 of the output core 22 and bring it from state zero to state one. The threshold value of the output core 22 allows a selection ratio of 3: 2. The size of the resistors 24 becomes like this chosen that the field strength in the output core 22 when resetting only two coupling cores 28 is smaller than the coercive force and when resetting all three coupling cores is greater than this value.

When the coupling cores 28 to zero and the output core 22 to one has been brought, the memory cores 12 of a clock pulse of the pulse generator 1A reset. This creates a voltage on their output windings 16 that drives a current through the transmission circuits. The coupling cores 28 offer him with their windings 26 only have a low resistance, since they are already in the state Zero. The current through the winding 20 of the output core 22 can therefore reset this core to zero. This creates on its output winding 32, at time A, an output signal.

Since the output core 22 only then turns to one because of its threshold value is brought when all coupling cores 28 are reset, he can also directly be brought to zero by a clock pulse from the pulse generator IC. Opposite to Resetting via the memory cores 12, this has the advantage that the output core can be magnetized more quickly. The additional necessary However, winding is only required if the one marked by (x - y - 4): a Load is very low resistance.

That used in this circuit to perform logic functions The basic principle is to use the coercive force of a core as a threshold value and the use of coupling cores with saturation in one of their two remanence states, at different times to a current of the same direction once a high and to offer a low resistance at other times. In the below This principle will emerge even more clearly in the exemplary embodiments described.

For a better understanding, the values of a tried and tested circuit according to FIG. 2 specified. Ring cores made of magnesium-manganese ferrite with an outside diameter of 2.5 mm, an inside diameter of 1.8 mm and a thickness of 0.8 mm were used. The magnetic cores of the circuit were assembled from these toroidal cores, namely the cores 12 and 22 contained four and the cores 28 two such toroidal cores. The windings 10 and 20 consisted of 5 turns each, the windings 14, 16, 26, 30 and 32 in the specified order of 15, 1.0, 30, 15 and 10 turns. Resistor 24 was 10 ohms. With these values, pulse amplitudes of 150 mA for 1, _, and 1.90 mA for lt were necessary.

The number of turns of the windings 26 is so high here only because all cores are made of the same ferrite material. Used for the coupling cores If a material with a smaller coercive force is used, the load on the Memory cores 12 already with a smaller one when the magnetization is reversed into state one Number of turns of the windings 26 are kept low enough.

The circuit according to FIG. 2, which is an AND circuit with three inputs shows, can easily be converted into such by other dimensioning of the resistors 24 can be modified with two inputs. Then the required electoral ratio is 2: 1. For AND circuits with more than three inputs, which have a selection ratio require that is smaller than 3: 2, the cores 12 and 22 are provided appropriately with a DC bias.

A basic logic circuit, which performs the logic function "exclusively OR" or "OR-BUT", delivers an output pulse when one and only one of two or more inputs is excited. Such an OR-BUT circuit with two inputs is shown in FIG. 3 shown. The input pulses are generated at a point in time B from the pulse generators I.xf; and Iyl; supplied to the input windings 40x and 40y of two memory cores 41x and 41y. The storage cores 41 each have an output winding 42 which is connected to the winding 46 of the associated output core 47 via the winding 43 of a coupling core 44 and a resistor 45. Each output core 47 is provided with a further winding 48, the direction of which is opposite to that of the winding 46. The circuit just mentioned is closed via this winding 48 in that the second end of the winding 46 is connected to ground via the winding 48 of the other output core. The output cores 47 still carry the output windings 50, which are connected in series to the load 52 in the same winding direction. A pulse generator IR resets the coupling cores 44 via the series-connected windings 54 . The storage cores 41 receive a direct current bias from the current source loc via the windings 56 and the output cores 47 via the windings 58. The pulse generator 1A resets the storage cores 41 via the windings 60 and the output cores 47 via the windings 62 by means of a clock pulse.

Initially, all nuclei may be in the zero state. If, for example, the pulse generator IxB now delivers a pulse at time B , the associated memory core 41x is brought into remanence state one, and a voltage is generated in the output winding 42x of this core, but not in the output winding 42y of the other memory core 41y. This voltage drives a current through the winding 43x of the coupling core 44x, the winding 46x of the output core 47x and the winding 48y of the other output core 47y. The direction of the current is such that it wants to bring the cores 44x and 47x into the state one and the core 47y into the state zero. The output core 47y, however, is already in this state, so that no change in flux takes place in it. The output core 47x cannot be remagnetized either, since the number of turns of the windings 46 is significantly smaller than that of the windings 43 and therefore the field strength generated in the core is smaller than the coercive force. Therefore, only the coupling core 44x can change its state from zero to one. Now a pulse from the pulse generator IR strongly resets this coupling core 44x back to zero, and the voltage generated at its winding 43x drives a current IR through which from the output winding 42x of the storage core 41x, - the winding 46x of the output core 47x and the Loop formed winding 48y of the output core 47y. This current seeks to bring the cores 41x and 47y to zero and the core 47x to one. However, since the cores 41 and 47 are premagnetized towards the state one by a direct current from the jellyfish Inc, the current cannot reset the memory core 41x. Just like the output core 47y, which is already in the zero state, the memory core 41x therefore offers; the current only has a small resistance, so that it can bring the output core 47x to one.

The cores 41x and 47x are now in state one and all other cores are in state zero. At a point in time A, the pulse generator 1A now resets these two cores 41x and 47x to zero by means of a clock pulse, and a pulse is generated at the output winding 50x which is communicated to the load 52.

If the pulse generator IyB had supplied the input pulse at time B , the process would have taken place in the cores marked with y, and the output core 47y would have supplied a pulse at time A. If only one input is excited, then the circuit emits an output pulse to the load 52.

But if the pulse generators IxB and IyB work at the same time, both coupling cores 44x and 44y are set to one. The effects of the currents IR "and IR ,, which occur simultaneously when resetting these cores to zero cancel each other out in the output cores 47 , since the currents have the same amplitude and the windings 46 and 48 have opposite winding directions. The output cores 47 are therefore not Obviously, there is no output signal even if none of the inputs is excited at time B, since then no core is brought out of the remanence state zero.

As already mentioned, the coupling cores 44 do not need to consist of the material with a rectangular hysteresis loop, but the storage cores 41 and the output cores 47 must have a pronounced threshold value, ie a kink in their hysteresis loop near the coercive force. If only magnetic cores made of rectangular material are used, the number of turns of the windings 43 must be selected to be correspondingly high. Tried and tested values for the number of turns ratio are 3: 1 for windings 42 and 46 and 5: 1 for windings 43 and 42. Windings 46 and 48 must have the same number of turns.

As a further embodiment of the invention, FIG. 4 that Circuit diagram of a so-called "half binary adder", d. H. an adder for two binary digits. In binary addition, the sum of two is different Digits a one and the sum of two identical digits a zero. A carryover only occurs with two non-zero digits. The logical function of the The sum can therefore be determined by an OR-BUT circuit and that of the carry realize through an AND circuit. The adder of FIG. 4 is from the OR-BUT circuit the F i g. 3 was created by adding another core 72 for the carry, its input winding 70 in the common return of the two transmission circuits is connected, which is shown in FIG. 3 happened across the crowd. Next carries the Core 72 a reset winding 76 which is fed by the pulse generator 1A, and an output winding 78 for the carry pulse. The core 72 also exists from a rectangular material with a pronounced threshold value. He is not from one Direct current premagnetized. For a better overview, FIG. 4 the individual Parts of the OR-BUT circuit are provided with the same reference numerals as in FIG F i g. 3.

If in the circuit according to FIG. 4 only one of the two entrances x and y are excited, the sum pulse to the load 52 arises on the same Way like the output pulse of the circuit according to FIG. 3. A transmission pulse of the output winding 78 of the core 72 to the load 75 does not arise because because of the threshold of core 72, a single stream IR "or IR" is through the input winding 70 is unable to re-magnetize the core to the state one, so that a clock pulse from the pulse generator 1A at time A could reset it.

If a signal is applied to both inputs, the output cores 47 are not influenced by the currents occurring when the coupling cores 44 are reset by a pulse from the pulse generator IR. Therefore, at time A at the load 52, there is also no sum pulse. The core 72, on the other hand, is brought into the state one by the currents IR, and IR, through its input winding 70, which in total exceed the threshold value. The following clock pulse from the pulse generator 1A resets it to zero, and the voltage pulse arising at its output winding 78 is output to the load 75 as a transfer pulse. The schematically indicated load arrangements 52 and 75 can belong to a further “half binary adder” and supplement the one described to form a “whole binary adder”.

As a guide for the dimensioning, some values are again specified. In a properly working circuit, the ferrite cores had one Threshold value flow of 670 milliampere turns corresponding to the coercive force, resistor 45 was 10 ohms, windings 40, 46, 48, 56, 70 and 74 passed of 5 turns each and the windings 42, 50, 54, 58, 60; 62 and 78 of 10 turns each. The windings 43 required 40 turns.

In Fig. 5, an INVERTER circuit is shown, which the logic Function of negation realized. It only supplies an output pulse if the input is not energized. The input signal is from the pulse generator SB the input winding 80s of the memory core 81s. Next is the memory core 81s is provided with an output winding 82s and a sliding winding 83s. the Output winding 82 s is via the winding 85 s of a coupling core 86s with the Input winding 84s of an output core 84 is connected. Another memory core 81 is triggered by a pulse generator 1B at time B with clock pulses its input winding 80 is fed. The sliding winding 83s is in series with one Similar sliding winding 83 connected to the pulse generator 1A, which the both memory cores are supplied with clock pulses at time A. Also the memory core 81 has an output winding 82 which is similar to that of the memory core 81s via the winding 85 of a coupling core 86 with a second input winding 88 of the output core 84 is connected. The coupling cores 86 and 86 s are from one Pulse generator IR to which they are connected with their series-connected windings 90 and 90s are connected, reset. The output core 84 finally still has an output winding 92 which provides the output signal to the load 95.

The sequence of the pulses from the individual pulse generators is shown in FIG. 6 shown. The pulse of the generator SB is drawn in dashed lines to indicate that this pulse can be applied optionally, but in the time interval from t1 to t2. The clock pulse of generator 1B occurs in the same time interval, while that of generator 1A only occurs in the time interval from t3 to t4. The reset pulse of the generator IR acts from t2 to t3. At time B, that is to say in the time interval from t1 to t2, the clock pulse of the generator 1B sets the memory core 81 from the remanence state zero to the state one. The voltage occurring at the output winding 82 drives a current through the winding 85, so that the coupling core 86 is also remagnetized to one. The output core 84 is not affected, since the number of turns of the winding 85 is significantly greater than that of the winding 88 on the output core 84. The volume of the storage core 81 is three times as large as that of the output core 84 and the volume of the coupling core 86, multiplied by the Turn ratio of winding 85 to winding 82 is at least as large as the volume of storage core 81. Then, after the end of the clock pulse from generator 1B in coupling core 86, a sufficiently large voltage pulse, i.e. a sufficiently large time integral, is stored via the voltage around output core 84 to be re-magnetized to state one when the coupling core 86 is reset by the pulse of the generator IR in the time interval from t2 to t3. The current occurring in the process cannot overcome the threshold value of the memory core 81, so that this core remains in the state one.

However, at time B there was an input signal through the pulse generator SB is applied, the coupling core would also follow 86 s in the time interval from t2 to t3 Reset to zero and a current through winding 84s of the output core 84 effect. Since the windings 88 and 84s have the same number of turns, but opposite Have winding sense, the effects of the two currents would cancel each other out, and the output core would not be affected. The output core 84 therefore becomes only brought to state one if no input signal was applied.

At time A, that is, in the time interval from t3 to t4, the Clock pulse from generator 1A returns the memory core 81 to zero. Because the coupling core 86 is already in the zero state, its winding 85 sets the current that occurs only a slight resistance to it. This current flows into the with a point marked end of the input winding 88 of the output core 84 and sets it returns to the zero state, provided it was previously due to the lack of an input pulse could get into state one. The resulting on its output winding 92 The voltage pulse is applied to the load 95 as an output pulse.

Was at time B a pulse from generator S, 3 on the input given to the circuit, the pulse from generator 1A also becomes the memory core 81 s is reset and a current is induced in its output winding 82s. The starting core 84, which remained in the zero state due to the presence of the input pulse, would generate a small glitch due to the current in its input winding 88 output the circuit. That from the output winding 82s of the memory core 81.s current flowing in the input winding 84s of the output core 84 is effective, however against the current in the input winding 88, so that practically no interference pulse occurs.

Claims (7)

Claims: 1. Transmission circuit for passing on an in a saturable magnetic core whose remanent flux is almost equal to its saturation flux is stored information in the form of a magnetization reversal of the magnetic core occurring current pulse to another magnetic core or another load, in which according to patent 1142 452 the transmission link between the storage magnetic core used and the load that causes undesired impulses to take effect when passing the information prevents a magnetic core with two stable Remanence states opposite polarity and that of storing The magnetic core used has a pronounced threshold value flooding, as a result characterized in that when entering the information in the first magnetic core by The magnetization of this magnetic core changes into the opposite remanence state The magnetization of the second magnetic core is also reversed and only when the magnetization is reversed of the second magnetic core sends the information to a third magnetic core serving as a load is delivered. 2. Circuit according to Claim 1, characterized in that the third Magnetic core has a pronounced threshold value flooding. 3rd circuit after claims 1 and 2, characterized in that the second magnetic core as a series impedance is switched. 4. Circuit for realizing the logical function of the conjunction using two or more arrangements according to claims 1 to 3, characterized in that the third magnetic core is common to all assemblies. 5. Circuit for realizing the logical function of incompatibility using of two or more arrangements according to claims 1 to 3, characterized in that that the third magnetic cores are interconnected in such a way that only one of the third magnetic cores can be remagnetized. 6. Realization circuit the logical function of negation using two arrangements according to the Claims 1 to 3, characterized in that the third magnetic core has both arrangements is common and that the input signal for one of the two arrangements of one Clock pulse generator is supplied. 7. Circuit for adding two binary digits using two arrangements according to claims 1 to 3, characterized in that that the third magnetic cores are connected to each other in such a way that only one the third magnetic core can be used to deliver the sum pulse and that for the A further, third magnetic core is provided for the transmission of the transmission pulse, of the two arrangements is common.